Mastitis in non-bovine dairy species, companion animals and breastfeeding mothers. Chris Knight

Mastitis in non-bovine dairy species, companion animals and breastfeeding mothers Chris Knight

Objectives To stimulate thought/discussion regarding the relevance and importance of mastitis and mastitis research in non-bovine farmed species To highlight issues related to diagnosis of mastitis in non-dairy farmed species To highlight the knowledge gap when comparing bovine and human mastitis To do this in a Nordic context

World milk production

Goat milk production

World Milk Production

Sheep mortality Cause of death diagnosed at autopsy Incidence (%) Mastitis 11 Acute fluke 7 Johnes disease 6 Ovine pulmonary adenocarcinoma 6 Bacterial bronchopneumonia 6 Chronic suppurative pneumonia 6 Pulmonary neoplasia 6 Other cause of death (individually minor events) 26 Autolysis 9 No diagnosis 17 No cause of death diagnosis 6 Strugnell and Lovatt (2013) Proc. BSAS 4(1) 14

Ovine mastitis Recent reviews: Conington et al 2008 (objective: increased genetic resistance) Mavrogianni et al 2011 (therapy) Estimates of prevalence in both dairy and meat sheep vary, but values in excess of 33% are reported In addition to S. aureus, Mannheimia haemolytica is a common isolate Modelling suggests that a 10% reduction in incidence would save 2.7M pa in the UK Texel industry

Caprine mastitis Recent review focused on diagnostic tools: Koop et al 2012 Typically lower incidence of clinical mastitis than in cattle, but higher subclinical Why? Interpretation of SCC data is different to that in cattle

Buffalo mastitis Joshi and Gokhale 2006, Ann. N.Y. Acad. Sci. Compared improved and periurban production Actually focused on bovine mastitis Cited evidence of lower subclinical mastitis incidence in buffalo compared to cattle (5-20% vs 10-50%) Clinical mastitis claimed to be between 1 and 10% Significant effect of season claimed but not supported by data (15.05 vs 13.97% and 8.89 vs 7.04%, rainy vs summer, cows vs buffalo) Very few truly comparative data, most rather old

Camel mastitis Several recent reports Typically 30-40% subclinical mastitis Typically 5-10% clinical mastitis SCC appears to be useful High incidence of blind quarters Traditional management probably predisposes to mastitis Pathogen profiles probably similar to cattle

Equine mastitis Very few reports since a number of short reviews in the 1980s A recent review of milking horse herds in Netherlands/Flanders identified 13 such farms

Canine mastitis Few scientific reports, mainly case studies Issues: Dairy farm reservoir (eg Streptococcus canis) Pseudopregnancy Perinatal mortality Chronic subclinical mastitis and carcinomas One experimental challenge study used Staphylococcus intermedius (Ververidis et al 2007) Therapy has been reviewed (Wiebe and Howard 2009) Feline mastitis is less well documented

Porcine mastitis Gerjets et al 2009, 2011 Mastitis-metritis-agalactia syndrome, postpartum dysgalactia syndrome, puerperal mastitis, coliform mastitis Typically around 13% of sows affected, range up to 60% in some herds Associated with E coli but cause and effect not established, and recent research shows no difference in infection rate or virulence factors between healthy and diseased sows Risk factors include increased fecundity, being a gilt, bith intervention. Birth induction and season are not risk factors

Risk analysis overview Category of animal Incidence Diagnosis Treatment Family herds Known, amenable Well developed Dairy cows AMS herds to management Developed Well developed Large herds improvement In development Some Other milked ruminants information, management intervention possible Less well developed Less well developed Non-milked ruminants Companion animals Very scarce information. Often wrongly(?) assumed to be low incidence Scarce information. Most do not lactate, so incidence probably low Poorly developed Reliance on lay knowledge Little opportunity Little opportunity Breastfeeding mothers Some information, quite variable. Probably similar incidence to well managed dairy cow herd Variable, self diagnosis and healthcare worker rates differ Variable, major debate regarding effectiveness of antibiotics but little data

Potential for use of high-dose oxytocin to improve diagnosis of mastitis in dairy cows and beef suckler cows Lina Jonsson, Christopher Knight and Kerstin Svennersten-Sjaunja Swedish University of Agricultural Sciences and University of Copenhagen lina.jonsson@miris.se chkn@sund.ku.dk

Aim Our objective was to investigate a possible physiological basis for the development of a single-visit milk-based mastitis diagnostic test suitable for use in beef suckler cows. We hypothesised that high-dose oxytocin would create leaky mammary tight junctions, increased SCC and shedding of pathogen into milk, and thereby provide a milk sample with enhanced diagnostic potential

Introduction The problem Subclinical Mastitis -Diagnosed as SCC > 200K cells/ml in milk from several milk samples Beef suckler cows -Assumed to have a low frequency of subclinical mastitis - Recent studies shows that this is not the case. Persson Waller K, Persson Y and Stengärde L (2012). Mastitis in beef cows: a threat against calf growth? CRU Report 27 p16. ISBN 978-91- 576-9013-5

Material and methods 14 Dairy cows. 10 cows with a previous history of high SCC (HIGH). 4 cows SCC < 50 000 cells/ ml milk (LOW). Milked twice a day over an 11 day study period. Milk samples were collected as shown in the next slide. At the AM milking on day 3, 100iu of oxytocin was given. The sample taken that afternoon, approx. 8 h after the oxytocin was given, was designated the test sample. Samples were analysed for mastitis pathogens, SCC and gross composition using standard methodologies.

Experimental Milking Experimental design Experimental Day Fore SCC, Bacteriology Bulk SCC, Composition Hind Bacteriology Day number 1 2 3 4 10 11 1 2 3 4 5 6 7 8 9 10 11 12 Sample number Oxytocin Test sample

Results No evidence of increased pathogens in sample 5 or 6. SCC increased markedly in sample 6 and recovered to pre-oxytocin levels thereafter.

SCC *10 3 / ml Results SCC (Individual HIGH cow) 3500 3000 2500 2000 1500 1000 500 RF RB LB LF 0 1 2 3 4 5 6 7 8 9 10111213141516171819202122 Milkings

SCC *10 3 / ml Results SCC (Individual LOW cow) 500 400 300 200 100 RF RB LB LF 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 Milkings

SCC *10 3 / ml Results ( Hard to categorize cow) 7000 6000 5000 4000 RF 3000 RB LB LF 2000 1000 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 Milkings

Results Diagnosed subclinical mastitis (quarters) Samples 1-5 (Milk) Test sample (Modified milk) 15 18 Missclassified at least once (quarters) 6 (40%) 2 (11%) Clinical signs (samples) 72 14 Missed by scc (samples) 25 (35%) 1 (7%)

Conclusions Measurement of SCC in the single sample collected approximately 8h after oxytocin administration was shown to have much better diagnostic potential than other single samples. High-dose oxytocin could be a useful mastitis diagnostic tool in beef suckler cows, and in dairy cows where frequent sampling is not possible.

Evolving dairy farms

Risk analysis overview Category of animal Incidence Diagnosis Treatment Family herds Known, amenable Well developed Dairy cows AMS herds to management Developed Well developed Large herds improvement In development Some information, Other milked ruminants management intervention possible Less well developed Less well developed Non-milked ruminants Companion animals Very scarce information. Often wrongly(?) assumed to be low incidence Scarce information. Most do not lactate, so incidence probably low Poorly developed Reliance on lay knowledge Little opportunity Little opportunity Breastfeeding mothers Some information, quite variable. Probably similar incidence to well managed dairy cow herd Variable, self diagnosis and healthcare worker rates differ Variable, major debate regarding effectiveness of antibiotics but little data

Human Mastitis Mastitis Mammitis Mastadenitis Milk fever

Self-diagnosis Health worker Definition required Pathogens Blocked ducts Cracked nipples Physiological mastitis Causes 3 rd NBC Meeting Copenhagen 2009 Suckling Breast pump Researcher Clinical vs Subclinical Diagnosis Mastitis Incidence Management Antibiotic: (Systemic) (Local) (Prophylactic) Acute phase response Analysis of milk Order of magnitude variation 3% to 30% Consequences Mother: Pain Anxiety Breast cancer? Baby: Nutrition Protection Disease vector Oxytocin Liniment Analgesia

Antibiotic use: Cochrane review

Management of mastitis: Cochrane review Crepinsek et al 2012 Five trials in total, 960 women A/B vs none: no significant difference (NSD) Specialist advice vs usual care: NSD Specialist diet vs normal diet: NSD Other therapies vs none: NSD

Chicken and egg? Why treat with antibiotic? Do blocked ducts cause mastitis? Or does mastitis cause blocked ducts? Why NOT treat with antibiotic?

Where to start? Post-feed routine Weaning strategy Early lactation strategy Hit recurrent mastitis hard